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Perni, Stefano, Hakala, Veera and Prokopovich, Polina 2014. Biogenic synthesis of antimicrobial
silver nanoparticles capped with L-cysteine. Colloids and Surfaces A: Physicochemical and
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Biogenic Synthesis of Antimicrobial Silver
Nanoparticles Capped with L-cysteine
Stefano Perni 1, Veera Hakala 1, Polina Prokopovich 1,2*
1 School of Pharmacy and Pharmaceutical Sciences, Cardiff University, Redwood Building, King
Edward VII Avenue, Cardiff, UK
2Institute of Medical Engineering and Medical Physics, School of Engineering, Cardiff University,
Cardiff, UK
* Corresponding author:
Dr. Polina Prokopovich e-mail:[email protected]
School of Pharmacy and Pharmaceutical Sciences
Cardiff University
Redwood Building, King Edward VII Avenue
Cardiff, UK
CF10 3NB
Tel: +44 (0)29 208 75820 Fax: +44 (0)29 208 74149
Abstract
The number of medical applications of silver nanoparticles is constantly expanding due to their high
bactericidal properties coupled with low toxicity towards mammalian cells. Because of this expanding
use of silver nanoparticles, novel methods of synthesis have been developed in order to achieve
nanoparticles preparation through inexpensive and environmentally friendly processes; biogenic
synthesis of silver nanoparticles is an approach that meets those requirements.
In this work, E. coli cultures centrigugates were used to synthesis L-cysteine capped silver
nanoparticles. The ratio between AgNO3 and L-cysteine has been proven to affect the size of the
nanoparticles: higher amount of L-cysteine returns smaller nanoparticles, but does not affect the
percentage of organic matter in the nanoparticles as determined through TGA.
The silver nanoparticles prepared had antimicrobial activity against E. coli and S. aureus with
Minimum Inhibitory Concentration (MIC) and Minimum Bactericidal Concentration (MBC)
independent of the nanoparticles size; for both bacterial species the values of MIC and MBC were the
same, 0.0432 mg/ml for E. coli and 0.0216 mg/ml for S. aureus.
Keywords: silver nanoparticles, E. coli, biogenic synthesis, S. aureus, green chemistry
Introduction
Nanoparticles offer an intermediate between bulk materials and individual atoms with unique
properties. Their chemical properties result from the high percentage of atoms on the surface of the
particle. This leads to increased reactivity which depending on the application can give increased
surface catalysis, improved loading of the surface or greater release of ions into solution [1].
Nanoparticles have been employed in many fields such as catalysis [2-4], ceramics [5], drug delivery
[6,7] and diagnostics and therapies of oncology [8]. The increasing detection of bacterial strains
capable of resisting one or more antibiotic has driven the research in the development and application
of nanomaterials to inactivate pathogens [9]; this is in virtue of the inability of such agents to induce
resistance in bacteria and the constantly decreasing efficacy of common antibiotics. Silver
nanoparticles antimicrobial properties have found application in bone cement [10], wound dressing
[11] catheters [12,13] and fabrics [14].
It is difficult to differentiate between antibacterial effects of ionic silver and Ag nanoparticles as all
nanoparticles release a degree of silver ions [15,16]. The antimicrobial effect of silver is thought to be
the combination of several mechanisms of action; for example, silver ions and small silver
nanoparticles (Ag-NPs) (less than 10nm) have been shown capable of entering the bacterial cytoplasm
and inhibit cell growth [17]. Furthermore, they are able to attach covalently to the surface of cell
membrane via phospholipids, inhibit cell wall formation, attach to ribosomal 30s subunit, attach to the
thiol groups of enzymes and interact with L-cycteine in bacterial peptides [18]. Silver nanoparticles
damage the cell wall and membranes and diffuse into the bacteria where they meditate the release of
potassium out of the cell [19] and destroy DNA by intercalating between bases [9,20]. Park et al. [18]
found that silver ions (Ag+ ) exhibit better bactericidal activity against E. coli and S. aureus under
aerobic conditions than under anaerobic conditions. Silver-mediated reactive oxygen species have
synergistic effects with thiol-grouping and the mechanisms are thought to be closely related [19].
Hwang et al. [20] also proposed a combined effect of Ag+ ions and Ag nanoparticles; once Ag+ ions
have started the creation of reactive oxygen species the membrane becomes damaged and Ag
nanoparticles can enter the cell causing further damage [20]. This was supported by Taglietti et al.
[21] who described a ‘short distance’ interaction mechanism of local physical action of the Ag
nanoparticles and ‘a long distance’ ion release mechanism.
Although metal nanoparticles have been synthesised by a variety of physical and chemical routes, it is
the reduction of metal salts that has become the standard route for their synthesis due to the flexibility
of the particles produced and its reproducibility. For example, to prepare silver nanoparticles, in
general ionic silver (Ag+) contained in a salt, generally AgNO3, is reduced to metal silver (Ag0)
through a reducing agent such as citrate [22], Al-alkoxide [23], NaBH4 [24], N,N-dimethyl formamide
[25] or sugars [26,27]. The nanoparticles can also be stabilized using chelating substances such as:
citrates [22,28], oleic acid [26], poly(acrylic acid) [29], starch [30] and glutamic acid [31] or prepared
with a capping agent that allows binding of other compounds to the nanoparticles such glutathione
[32] or tiopronin [33]. Silver nanoparticles of very different geometrical (size and shape)
characteristics can be obtained modifying the reaction conditions. However, many of these synthetic
routes employ chemical reagents or physical agents that are expensive and/or harmful; the increasing
interest in using low energy processes and safe chemicals (so called “green chemistry”) has, therefore,
originated novel synthetic routes for the preparation of nanoparticles. Plants extracts [34,35], fungi
[36-38] and bacteria [39-41] have been used for synthesising silver nanoparticles, but the faster
growth rate of bacteria makes their use more industrially appealing. E. coli is a widely used bacteria
used in biotechnology and biogenic synthesis of nanomaterials [42-44]. In these works no capping
agent was employed, therefore limiting the possibility of further bioconjugation, or size control;
moreover the antimicrobial properties of the synthesised nanoparticles was not always determined
[43,44].
In this paper, we employed Escherichia coli surnatant to prepare silver nanoparticles capped with
cysteine; we determined how the ratio between silver salt and cysteine affects the size, composition
and antimicrobial properties of the nanoparticles against E. coli and Staphylococcus aureus.
Materials and Methods
Chemical
All chemicals were purchased from Sigma-Aldrich, UK unless stated
Bacteria
E. coli MG1655 and S. aureus NCTC 6571 were stored frozen at -80°C; 10 l of the frozen stock of
cells were streaked on LB Agar and incubated for 24 h at 30°C; the cultures obtained were kept in a
fridge at 4°C for no more than a week.
Nanoparticles synthesis
A loopful of E. coli cells was employed to inoculate 200 ml of fresh sterile LB broth contained in a
500 ml Erlenmyer flasks; the broth was incubated for 24 hours at 30°C under shaking at 70 rpm.
Following incubation, cultures were poured aseptically into sterile 750 ml polypropylene centrifuge
bottles (Beckman Coulter UK Ltd.) centrifuged at 1851g for 10 minutes in a centrifuge (JOUAN 420)
fitted with a swinging bucket rotor. After centrifugation, the surnatant was transferred in a clean
sterile 500 ml Erlenmyer flask, AgNO3 and L-cysteine were added from stock solutions of 1 M to
reach a final concentration of 1 mM or 5 mM. The flasks were then incubated for 24 hours at 30°C
under shaking at 70 rpm to allow the synthesis of nanoparticles to proceed.
The nanoparticles were separated through the addition of 50 ml of methanol and centrifuged at 1851g
for 10 minutes in a centrifuge (JOUAN 420) fitted with a swinging bucket rotor, washed three times
with distilled water and dried at 40°C.
Nanoparticles characterization
TEM – particles size
For transmission electron microscopy (TEM) characterization a 4 µl droplet of nanoparticles
suspension was placed on a plain carbon-coated copper TEM grid and allowed to evaporate in air
under ambient laboratory conditions for several hours. Bright field TEM images were obtained using
a TEM (Philips CM12, FEI Ltd, UK) operating at 80kV fitted with an X-ray microanalysis detector
(EM-400 Detecting Unit, EDAX UK) utilising EDAX’s Genesis software. Typical magnification of
the images was x 100 000. Images were recorded using a SIS MegaView III digital camera (SIS
Analytical, Germany) and analyzed with the computer program ImageJ; the diameters of at least 150
particles for each synthetic condition were determined.
UV-Vis spectra
Absorption spectra of the nanoparticles suspensions were recorded using a spectrophotometer U-3000
(Hitachi High-Technologies Europe GmbH) at wavelength interval of 1 nm.
TGA
Thermogravimetric analysis (TGA) was performed using a Stanton Redcroft, STA-780 series TGA.
Data was recorded from 25 to 1000 °C with a constant heating rate of 10 °C minute-1.
FTIR
A Shimadzu 8700 FT-IR spectrometer was employed to collect Infrared spectra (3800 to 500 cm−1) of
samples pressed into a KBr plate
Antimicrobial test
In the antimicrobial experiment silver nanoparticles were added to sterile Brain-Heart Infusion (BHI)
broth at a concentration of 0.0864 mg/ml. The suspension was stored in a refrigerator (5°C) before
use. A loopful of E. coli cells was employed to inoculate 10 ml of sterile BHI contained in a sterile
tube and incubated at 37 °C for 24 hours statically. The same procedure was repeated with S. aureus.
After incubation of 24 hours, the concentration of both cells was 109 CFU/ml as determined through
serial plating. The cells suspension were diluted 1:10000 using sterile BHI broth giving an initial cell
count of 105 CFU/ml. 50 µl of sterile BHI broth added in wells in a row of a 96 wells plate. The silver
nanoparticles solution 0.864 mg/ml (50 µl) was added and carefully mixed. Then 50 µl were pipette
out of the first well and transferred to next the well on the right and mixed. A plate reader was used to
measure the optical density (at 600nm), another reading was taken after the well plate had been
incubated for 24 hours in 37 °C. The Minimum Inhibitory Concentration (MIC) was determined from
the plate reader as the lowest concentration of nanoparticles capable of preventing cell growth.
The Minimum Bactericidal Concentration (MBC) was determined after establishing MIC for each
bacterium. 25 µl were taken from each well where the concentration of nanoparticles was greater than
MIC and either spread on BHI Agar plates or serially diluted into 225 µl of sterile PBS and spread on
BHI Agar. Plates were placed in an incubator for 24 hours at 37 °C before reading the results. The
MBC is lowest concentration of Ag nanoparticles solution that showed a reduction of number of cells
from the initial count of 105 CFU/ml.
Results
The UV-vis spectrum of the nanoparticles suspension exhibited a clear absorption maximum at ~430
nm for AgNO3:L-cysteine of 1:1 and 5:5 and ~440 nm when the AgNO3:L-cysteine ratio was1:5
(Figure 1); TEM analysis (Figure 2) revealed that the silver nanoparticles synthesized were rounded
regardless of the ratio AgNO3:L-cysteine. The distributions of particles diameters are presented in
Figure 3 along with the correspondent Gaussian distribution; when the ratio AgNO3:L-cysteine was
1:1 or 5:5 the particles had a mean diameter of 14.9±2.8 and 13.8±2.8 nm respectively, whilst the
nanoparticles obtained with a ratio AgNO3:L-cysteine of 1:5 had a mean diameter of 5.0±1.9 nm. It is
evident that the diameters followed a Gaussian distribution (Figure 3). No nanoparticles were
synthesised when no L-cysteine was added along with AgNO3 or when both L-cysteine and AgNO3
were added to PBS.
The presence of L-cysteine on the surface of the nanoparticles was investigated through FTIR (Figure
4); in all case, L-cysteine was found on the surface of the nanoparticles as the characteristic peaks of
pure L-cysteine were also found when the nanoparticles were analysed.
The effect of the concentration of AgNO3 and L-cysteine on the organic composition of the
nanoparticles was investigated through TGA (Figure 5). It appeared that when the ratio AgNO3 to L-
cysteine was 1:1 and 5:5 the behaviour was similar up to 300 °C. All silver nanoparticles exhibited a
reduction of about 20% at 300 °C, but overall the nanoparticles synthesised with a ratio AgNO3 to
cysteine was 1:5 returned the lowest mass reduction.
MIC and MBC were determined to assess the antimicrobial properties of the synthesised silver
nanoparticles against two bacterial species: E. coli and S. aureus (Table 1). The synthetic conditions
tested here, and consequently their effect on the nanoparticles characteristics, did not influence the
antimicrobial activity against either of the bacterial species. Furthermore, both E. coli and S. aureus
exhibited the same value of MIC and MBC (0.0432 mg/ml and 0.0216 mg/ml respectively).
Discussion
Stabilisation is necessary to obtain nanoparticles in the range below 100 nm, furthermore,
nanoparticles stability is also required for practical application. Unwanted overgrowth is suppressed
by coating the surface of nanoparticles during synthesis with a capping layer of organic molecules.
This capping agent reduces the surface energy of the nanoparticles enhancing their separation and
prevents further agglomeration. Depending on the properties of this capping agent, the characteristics
(geometry and solubility) of the nanoparticles can be controlled. The choice of capping agent must be
directed by the characteristics and application of the intended nanoparticles; for biological
applications, polypeptides (gluthatione) [21,45,46], tiopronin [10,33] and aminoacids have been
previously employed [31,45]. The common feature of these compounds is the presence of sulphur
whose strong affinity for Ag results in coverage of the nanoparticles and provides stability during
nanoparticles ripening. Increasing the amount of capping agent, from a ratio AgNO3:L-cysteine of 1:1
to 1:5, resulted in a reduction of the mean particles diameter as the additional cysteine stabilised the
particles further, consequently, the nanoparticles reached maturation at smaller size; similar results
were found using tiopronin as capping agent [10]. Moreover, the size of the nanoparticles was not
affected by the amount of AgNO3 and cysteine but only by the ratio, however it was not possible to
test whether a AgNO3:L-cysteine of 5:25 would return the same particles size distribution as a ratio
1:5 as L-cysteine was not soluble at this concentration. The different nanoparticles size caused by
varying amounts of AgNO3 and L-cysteine is also responsible for the slight shift in absorption
maximum in the UV-vis spectrum. It has been shown that another way of controlling nanoparticles
size is through the reaction temperature [38,43], with higher temperatures resulting in smaller
particles. AgNO3 concentration and pH have been proven controlling parameters of the nanoparticles
size during biogenic synthesis, with the smallest nanoparticles achievable at an optimum value of such
parameters [43]. Our approach, through the reagents ratio, seems more energy and environmental
friendly as the higher the reaction temperatures the higher the energy cost associate to the synthesis.
The presence of cysteine on the surface of the nanoparticles was confirmed further by FTIR as the
spectra of the nanoparticles were similar to pure L-cysteine; furthermore, TGA analysis showed the
presence of organic matter in the nanoparticles as mass reduction was detected at about 200 °C. The
different synthetic conditions did not influence the proportion of L-cysteine in the nanoparticles as
shown by TGA (Figure 5), however, as different ratios of reagents resulted in nanoparticles with
various diameters, the number of L-cysteine molecules per silver atoms varied with changing reagents
ratios.
In order to unequivocally prove that the synthesis of nanoparticles is performed by an extracellular
compound(s) produced by the growing E. coli cells we performed the synthetic step using either fresh
medium or PBS, in both cases no nanoparticles were detected. The reducing agent is either an
extracellular enzyme or another non enzymatic compound produced by E. coli and released during
growth [47]. Two enzymes, NADPH-dependant reductase [48] and nitroreductase NfsA [49], have
been proven involved in the reduction of Ag+ to Ag0. Reducing sugars are thought to be responsible
for the non enzymatic reduction; these are more likely to be found in plant extracts [48].
Another green method of synthesising nanoparticles recently gaining a lot of attention employs plants
extract to reduce metal ions [50-53]; despite the proven efficacy and flexibility of this process, the use
of bacterial cultures sub-products, such as filtrate or centrifugate, is likely to lead to more efficient
and cheaper industrial processes as the cost and time required to grow cells are smaller and shorted,
respectively, that growing plants and extracting compounds. For the same reason, biogenic synthesis
performed using bacteria is a more appealing process than fungi as the growth kinetics of eukaryotic
cells are comparably slower than prokaryotic organisms. A variety of bacteria species have been
employed to perform biogenic synthesis of nanoparticles, i.e. Streptococcus thermophilus,
Pseudomonas putida and Bacillus cereus [42,54], nevertheless the use of non-pathogenic bacteria,
such as E. coli MG1655 employed here, is ultimately a critical factor in biogenic synthesis of
nanoparticles to become an industrially relevant approach.
The antimicrobial activity of the nanoparticles synthesised in this work was tested against Gram-
positive S. aureus and Gram-Negative bacteria E. coli that are some of the most common
microorganisms causing infections. The antimicrobial action of a compound can be classified as:
inhibitory, when the concentration of the microorganisms does not increase with time compared to an
expected cell growth in absence of the chemical; or bactericidal was the concentration of the
microorganisms decrease upon exposure to the compound. Antibiotics generally exhibit inhibitory
activity at low concentrations and bactericidal at high doses.
The silver nanoparticles presented in this work exhibited an identical value of MIC and MBC;
Panacek et al. [27] also noted the same behaviour with silver colloid nanoparticles in their
experiments. These findings suggest that Ag nanoparticles damage the bacteria irreplaceably and the
action is more bactericidal than inhibitory, therefore, unlikely to induce the insurgence of resistance.
Ag nanoparticles smaller than 10 nm have been shown to have a high degree of interaction and
capacity to enter the cells [55]. However, size is not the only determining factor in assessing
nanoparticles antimicrobial activity, for example Prokopovich et al. [10] have shown that silver
nanoparticles capped with tiopronin with a diameter of 10 nm were more antimicrobial than
nanoparticles with 5 nm diameter, this was attributed to the higher silver content of the larger
nanoparticles. Also the shape of the nanoparticles plays a significant role in their antimicrobial
activity. Triangular, spherical, rod particles demonstrated antimicrobial activity in decreasing order
[9].
The higher resistance of E. coli cell to Ag nanoparticles compared to S. aureus, demonstrated by the
lower MBC values for the latter (43.2 mg/ml and 21.6 mg/ml respectively), is a general trend
associated to the structural differences between Gram positive and Gram negative bacterial cell [56].
.
Conclusions
The surnatant obtained after centrifuging E. coli cultures was employed to synthesis Ag nanoparticles
capped with L-cysteine. The higher the ratio AgNO3: L-cysteine the smaller the diameter of the
nanoparticles.
The nanoparticles prepared showed antibacterial activity against both Gram-positive S. aureus and
Gram-Negative bacteria E. coli; MIC and MBC were determined to be 21.6 mg/ml and 43.2 mg/ml,
respectively. Differences in ratios of AgNO3 and L-cysteine during synthesis did not influence the
antibacterial activity of the Ag nanopartilcles. Identical MIC and MBC values indicated Ag
nanopartilces having a bactericidal mechanism of action unlikely to induce the insurgence of
resistance.
Acknowledgements
PP thanks Arthritis Research UK (ARUK: 18461) for funding.
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Table 1. MIC and MBC of biogenically synthesised Ag NP capped with L-cysteine for E. coli and S. aureus
Bacteria 1:1 mol 1:5 mol 5:5 mol
E. coli MIC
0.0432 mg/ml 0.0432 mg/ml 0.0432 mg/ml
S. aureus 0.0216 mg/ml 0.0216 mg/ml 0.0216 mg/ml
E. coli MBC
0.0432 mg/ml 0.0432 mg/ml 0.0432 mg/ml
S. aureus 0.0216 mg/ml 0.0216 mg/ml 0.0216 mg/ml
Figure caption
Figure 1 UV-vis absorption spectra of of Ag NP synthesized with different ratios of AgNO3 and
cysteine.
1:1 AgNO3:L-cysteine 1:5 AgNO3:L-cysteine 5:5 AgNO3:L-cysteine
Figure 2 TEM images of nanoparticles. Bar equal to 100 nm.
(a) 1:1 AgNO3:L-cysteine (b) 1:5 AgNO3:L-cysteine (c) 5:5 AgNO3:L-cysteine
Figure 3 Size distribution of Ag NP synthesized with different ratios of AgNO3 and cysteine. Lines
represent Gaussian fitting and columns experimental data
1:1 AgNO3:L-cysteine 1:5 AgNO3:L-cysteine 5:5 AgNO3:L-cysteine
1:1 AgNO3:L-cysteine 1:5 AgNO3:L-cysteine 5:5 AgNO3:L-cysteine
Figure 4 Fourier Transformed Infra Red spectra (FTIR) of the three sets of nanoparticles and pure
cysteine.
1:1 AgNO3:L-cysteine 1:5 AgNO3:L-cysteine 5:5 AgNO3:L-cysteine
L-cysteine
Figure 5 Thermal Gravimetric Analysis of the three sets of nanoparticles.
1:1 AgNO3:L-cysteine 1:5 AgNO3:L-cysteine 5:5 AgNO3:L-cysteine
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5